Ultrastructural visualization of the internalization of low density lipoprotein by human placental cells

Summary Low density lipoproteins (LDL) were conjugated to colloidal gold to visualize the route for internalization of LDL in the cultured cells of human term placenta. Cells were obtained from placental villi (caesarian section) by a standard trypsin-DNase dispersion method followed in some cases by a Percoll gradient centrifugation step. Employing electron microscopy it was observed that after 3 days of culture, cells obtained by trypsin-DNAse dispersion were a mixture of macrophages, mononucleated cells and large multinucleated cells. When the cells were incubated for 3 days after the Percoll purification, essentially multinucleated cells identical to the syncytiotrophoblast were present. The number of LDL receptor was increased by preincubation in medium with lipoprotein depleted serum. In binding experiments cells incubated at 4° C for 2 h with medium containing gold LDL conjugates showed gold LDL attached to the plasma membrane without characteristic localization. After incubation with gold LDL at 37° C for various times, the three cellular types showed ligand internalization. Gold LDL endocytosis involved first coated pits but also uncoated plasmalemmal invaginations. Then gold LDL was further observed in coated and non coated vesicles, smooth walled endosomes, multivesicular bodies and tubular vesicles. Lastly free gold particles were observed in lysosome like dense bodies. These results prove the internalization of gold LDL conjugates by human cultured placental cells, particularly by syncytiotrophoblast like multinucleated cells. This accumulation of LDL (the major cholesterol carrying protein in humans) is recognised to be responsable for the exogenous cholesterol supply indispensable to the progesterone biosynthesis and cellular growth of the placenta.     

Conjugates of colloidal gold with native and acetylated low density lipoproteins for ultrastructural investigations on receptor-mediated endocytosis by cultured human monocyte-derived macrophages

Summary The morphological aspects of the binding and internalization of low density lipoproteins (LDL) and acetylated low density lipoproteins (AcLDL) by cultured human monocyte-derived macrophages were investigated. For this purpose, LDL and AcLDL were conjugated to 20 nm colloidal gold particles. After incubation of the cells with the conjugated lipoproteins at 4° C some LDL-or AcLDL-gold complexes were found to be attached to the cell surface, but without characteristic localization. However, after incubation of the cells at 8° C with either LDL-gold or AcLDL-gold, lipoprotein-gold complexes were present in clusters on the plasma membrane, often in coated pits. Cells incubated at 37° C for various time periods showed internalization of both LDL- and AcLDL-gold complexes via small coated and non-coated vesicles and processing of the complexes in smooth-walled endosomes. When the cells were pulse-chased with LDL- or AcLDL-gold for 30 min at 37° C, the gold conjugates occurred in dense bodies, probably lysosomes. The results suggest that although native and modified LDL are reported to be metabolized differently by macrophages, the morphological aspects of the endocytosis of LDL and AcLDL by cultured human monocyte-derived macrophages are similar.     

Conjugates of colloidal gold with native and acetylated low density lipoproteins for ultrastructural investigations on receptor-mediated endocytosis by cultured human monocyte-derived macrophages

The morphological aspects of the binding and internalization of low density lipoproteins (LDL) and acetylated low density lipoproteins (AcLDL) by cultured human monocyte-derived macrophages were investigated. For this purpose, LDL and AcLDL were conjugated to 20 nm colloidal gold particles. After incubation of the cells with the conjugated lipoproteins at 4 degrees C some LDL- or AcLDL-gold complexes were found to be attached to the cell surface, but without characteristic localization. However, after incubation of the cells at 8 degrees C with either LDL-gold or AcLDL-gold, lipoprotein-gold complexes were present in clusters on the plasma membrane, often in coated pits. Cells incubated at 37 degrees C for various time periods showed internalization of both LDL- and AcLDL-gold complexes via small coated and non-coated vesicles and processing of the complexes in smooth-walled endosomes. When the cells were pulse-chased with LDL- or AcLDL-gold for 30 min at 37 degrees C, the gold conjugates occurred in dense bodies, probably lysosomes. The results suggest that although native and modified LDL are reported to be metabolized differently by macrophages, the morphological aspects of the endocytosis of LDL and AcLDL by cultured human monocyte-derived macrophages are similar.     

Visualization of binding and receptor-mediated uptake of low density lipoproteins by human endothelial cells

Low density lipoproteins (LDL) were conjugated to colloidal gold for investigation of the ultrastructural aspects of binding and receptor-mediated internalization of LDL by cultured endothelial cells from the human umbilical artery and vein. The number of LDL receptors was increased by preincubation in lipoprotein-depleted serum. When the cells were incubated with LDL-gold particles for 2 h at 4 degrees C, the complexes were found in coated pits as well as in clusters attached to the plasma membrane. Small vesicles containing a few LDL-gold complexes appeared in the cytoplasm close to the plasma membrane when the cells were incubated with the conjugate for 5 min at 37 degrees C. After 15 min at 37 degrees C, larger vesicles with a pale matrix and membrane-orientated LDL-gold complexes were seen. After incubation for 30 min at 37 degrees C, colloidal gold particles were present in dense bodies. Quantification of the binding of LDL-gold complexes to the plasma membrane at 4 degrees C showed no differences between arterial and venous endothelial cells.     

Uptake of gold- and [3H]cholesteryl linoleate-labeled human low density lipoprotein by cultured rat granulosa cells: cellular mechanisms involved in lipoprotein metabolism and their importance to steroidogenesis

We used electron microscopy, acid hydrolase cytochemistry, and biochemistry to analyze the uptake and metabolism of colloidal gold- and [3H]cholesteryl linoleate-labeled human low density lipoprotein (LDL) by cultured rat granulosa cells. The initial interaction of gold-LDL conjugates with granulosa cells occurred at binding sites diffusely distributed over the plasma membrane. After incubation with ligand in the cold, 99.9% of the conjugates were at the cell surface but less than 4% lay over coated pits. Uptake was specific since it was decreased 93-95% by excess unconjugated LDL and heparin, but only 34-38% by excess unconjugated human high density lipoprotein. LDL uptake was related to granulosa cell differentiation; well-luteinized cells bound 2-3 times as much gold-LDL as did poorly luteinized cells. Ligand internalization was initiated by warming and involved coated pits, coated vesicles, pale multivesicular bodies (MVBs), dense MVBs, and lysosomes. A key event in this process was the translocation of gold-LDL conjugates from the cell periphery to the Golgi zone. This step was carried out by the pale MVB, a prelysosomal compartment that behaves like an endosome. Granulosa cells exposed to LDL labeled with gold and [3H]cholesteryl linoleate converted [3H]sterol to [3H]progestin in a time-dependent manner. This conversion was paralleled by increased gold-labeling of lysosomes and blocked by chloroquine, an inhibitor of lysosomal activity. In brief, granulosa cells deliver LDL to lysosomes by a receptor-mediated mechanism for the hydrolysis of cholesteryl esters. The resulting cholesterol is, in turn, transferred to other cellular compartments, where conversion to steroid occurs. These events comprise the pathway used by steroid-secreting cells to obtain the LDL-cholesterol vital for steroidogenesis.     

Filipin-cholesterol complexes form in uncoated vesicle membrane derived from coated vesicles during receptor-mediated endocytosis of low density lipoprotein

Filipin has been widely used as an electron microscopic probe to detect 3-beta-hydroxysterols, principally cholesterol, in cellular membranes. When it complexes with sterol, it forms globular deposits that disrupt the planar organization of the membrane. Previous studies have shown that coated pits and coated vesicles, specialized membranes involved in receptor-mediated endocytosis, do not appear to bind filipin. This has led to the suggestion that these membranes are low in cholesterol compared with the remainder of the plasma membrane. Since coated endocytic vesicles become uncoated vesicles during the transport of internalized ligands to the lysosome, we have carried out studies to determine whether or not the membranes that surround these transport vesicles are unable to bind filipin and therefore, are also low in cholesterol. Cells were incubated with ferritin-conjugated ligands that bind to low density lipoprotein (LDL) receptors in coated pits. After allowing internalization of the conjugates, we fixed the cells in either the presence or absence of filipin. This permitted us to identify all of the vesicles involved in the transport of LDL to the lysosome and to determine whether the membranes of these vesicles were able to bind filipin. We found that, coordinate with the dissociation of the clathrin coat from the endocytic vesicles, the membranes became sensitive to the formation of filipin-sterol complexes. Furthermore, all of the uncoated endocytic vesicle membranes, as well as the lysosomal membranes, bound filipin. This suggests either that coated membrane contains normal cholesterol levels, which is not easily detected with filipin, or that cholesterol rapidly moves into endocytic vesicles after the clathrin coat dissociates from the membrane.     

Hepatic binding and internalization of low density lipoprotein-gold conjugates in rats treated with 17 alpha-ethinylestradiol

Receptor-mediated hepatic uptake of low density lipoproteins (LDL) conjugated to colloidal gold was studied by perfusion of livers from rats treated for 5 d with 17 alpha-ethinylestradiol. Estrogen treatment resulted in a marked decrease in serum lipid and lipoprotein concentrations. After 15 min of perfusion the conjugate was bound to the hepatic microvilli of both control and estrogen-treated rats; the estrogen-treated rats showed an 8- to 11-fold greater number of membrane-bound conjugates. The conjugates were bound to the membrane receptor by the LDL particle because the gold granules were regularly displaced from the membrane by 20 +/- 3.2 nm, the diameter of LDL. Internalization of the conjugate, evident by gold particles in multivesicular bodies, occurred at coated pits at the base of the microvillus where coated vesicles containing a single gold-LDL conjugate were released. After 1 h of perfusion, the livers from the estrogen-treated rats showed all phases of endocytosis and incorporation into multivesicular bodies of the conjugate. After 2 h of perfusion, there was congregation of gold-labeled lysosomes near the bile canaliculi. Gold-LDL conjugates were also observed to bind and be internalized by Kupffer cells and sinusoidal endothelium. These findings indicate that estrogen treatment induces hepatic receptors for LDL. The catabolic pathway of binding and endocytosis of the conjugate is similar to that seen in fibroblasts, although slower. Because gold-LDL conjugates were also present in the Kupffer and endothelial cells, the uptake of LDL by the liver involves the participation of more than a single cell type.     

Role of the coated endocytic vesicle in the uptake of receptor-bound low density lipoprotein in human fibroblasts.

125I-labeled and ferritin-labeled low density lipoprotein (LDL) were used as visual probes to study the surface distribution of LDL receptors and to examine the mechanism of the endocytosis of this lipoprotein in cultured human fibrobasts. Light microscopic autoradiograms of whole cells incubated with 125I-LDL at 4 degrees C showed that LDL receptors were widely but unevenly distributed over the cell surface. With the electron microscope, we determined that 60-70% of the ferritin-labeled LDL that bound to cells at 4 degrees C was localized over short coated segments of the plasma membrane that accounted for no more than 2% of the total surface area. To study the internalization process, cells were first allowed to bind ferritin-labeled LDL at 4 degrees C and were then warmed to 37 degrees C. Within 10 min, nearly all the surface-bound LDL-ferritin was incorporated into coated endocytic vesicles that were formed by the invagination and pinching-off of the coated membrane regions that contained the receptor-bound LDL. With increasing time at 37 degrees C, these coated vesicles were observed sequentially to migrate through the cytoplasm (1 min), to lose their cytoplasmic coat (2 min), and to fuse with either primary or secondary lysosomes (6 min). The current data indicate that the coated regions of plasma membrane are specialized structures of rapid turnover that function to carry receptor-bound LDL, and perhaps other receptor-bound molecules, into the cell.     

Tissue-specific sorting of the human LDL receptor in polarized epithelia of transgenic mice

The distribution of human low density lipoprotein (LDL) receptors was studied by immunofluorescence and immunoelectron microscopy in epithelial cells of transgenic mice that express high levels of receptors under control of the metallothionein-I promoter. In hepatocytes and intestinal epithelial cells, the receptors were confined to the basal and basolateral surfaces, respectively. Very few LDL receptors were present in coated pits or intracellular vesicles. In striking contrast, in the epithelium of the renal tubule the receptors were present on the apical (lumenal) surface where they appeared to be concentrated at the base of microvilli and were abundant in vesicles of the endocytic recycling pathway. Intravenously administered LDL colloidal gold conjugates bound to the receptors on hepatocyte microvilli and were slowly internalized, apparently through slow migration into coated pits. We conclude that (a) sorting of LDL receptors to the surface of different epithelial cells varies with each tissue; and (b) in addition to a signal for clustering in coated pits, the LDL receptor may contain a signal for retention in noncoated membrane that is manifest in hepatocytes and intestinal epithelial cells, but not in renal epithelial cells or cultured human fibroblasts.     

Binding and degradation of proteoglycans by cultured arterial smooth muscle cells. I. Endocytosis and intracellular translocation of proteoglycan-gold conjugates

Proteoglycans (Mr approximately 200 000) isolated from bovine arterial tissue were decorated with 17 nm diameter gold particles for tracing in electron microscopic thin sections and surface replicas. Lysine and arginine residues of their proteoglycan protein core are assumed to be essential for gold conjugation. The resulting proteoglycan-gold conjugates, which appear as pearl string-like gold strands of about 170 nm in length were used to visualize binding, endocytosis and intracellular translocation of proteoglycans by homologous cultured arterial smooth muscle cells. The proteoglycan-gold conjugates bind to coated as well as to non-coated cell surface membrane areas at 4 degrees C. This is followed by the formation of membrane invaginations. Postincubation at 37 degrees C leads to a time-dependent uptake of proteoglycan-gold conjugates via non-coated and coated vesicles which after fusion are translocated to multivesicular bodies and to large sized vesicles within 1 h. After conversion of these vesicles to lysosomal compartments the gold particles are uncoupled from the proteoglycans and are concentrated within residual vacuoles. From these vacuoles the gold particles are extruded. In contrast to the surface-bound proteoglycan-gold conjugates the released gold particles are condensed to bulky aggregates. The results, which include competition, inhibition and pulse chase experiments, extend biochemical data on endocytosis and degradation of proteoglycans.     

Biochemical and morphological effects of gentamicin in human proximal tubular cells: effects on lipid and lipoprotein metabolism

The effects of gentamicin, an antibiotic used extensively for antimicrobial therapy on the ultrastructure, binding, internalization, degradation, and cholesterol esterification of low-density lipoproteins, were investigated in cultured human proximal tubular cells. Cells were incubated with 0.3 mM gentamicin for 21 days with the following observations. Cells treated with gentamicin contained numerous "myeloid bodies." The binding, internalization, and degradation of 125I-labeled low-density lipoproteins ([125I]LDL) in cells treated with gentamicin was twofold lower than control cells. Pulse-chase experiments demonstrated that gentamicin did not impair the internalization of receptor-bound LDL and their subsequent transport to the lysosome. The relative amounts of [125I]LDL displaced by increasing concentrations of unlabeled LDL were the same in both gentamicin-treated and control cells. This pattern was reflected in the cell surface binding, internalization, and degradation of [125I]LDL. Gentamicin did not alter the degradation of [125I]LDL in cell homogenates at 4.0. The data suggest that gentamicin decreases the receptor-mediated endocytosis of LDL and subsequent lipid metabolism.     

Hemopexin joins transferrin as representative members of a distinct class of receptor-mediated endocytic transport systems

Receptor-mediated transport of heme by hemopexin in vivo and in vitro results in catabolism of heme but not the protein, suggesting that intact apohemopexin recycles from cells. However, until now, the intracellular transport of hemopexin by receptor-mediated endocytosis remained to be established. Biochemical studies on cultured human HepG2 and mouse Hepa hepatoma cells demonstrate that hemopexin is transported to an intracellular location and, after endocytosis, is subsequently returned intact to the medium. During incubation at 37 degrees C, hemopexin accumulated intracellularly for ca. 15 min before reaching a plateau while surface binding was saturated by 5 min. No internalization of ligand took place during incubation at 4 degrees C. These and other data suggest that hemopexin receptors recycle, and furthermore, incubation with monensin significantly inhibits the amount of cell associated of heme-[125I]hemopexin during short-term incubation at 37 degrees C, consistent with a block in receptor recycling. Ammonium chloride and methylamine were less inhibitory. Electron microscopic autoradiography of heme-[125I]hemopexin showed the presence of hemopexin in vesicles of the classical pathway of endocytosis in human HepG2 hepatoma cells, confirming the internalization of hemopexin. Colloidal gold-conjugated hemopexin and electron microscopy showed that hemopexin bound to receptors at 4 degrees C is distributed initially over the entire cell surface, including microvilli and coated pits. After incubation at 37 degrees C, hemopexin-gold is located intracellularly in coated vesicles and then in small endosomes and multivesicular bodies. Colocalization of hemopexin and transferrin intracellularly was shown in two ways. Radioiodinated hemopexin was observed in the same subcellular compartment as horseradish peroxidase conjugates of transferrin using the diaminobenzidine-induced density shift assay. In addition, colloidal gold derivatives of heme-hemopexin and diferric transferrin were found together in coated pits, coated vesicles, endosomes and multivesicular bodies. Therefore, hemopexin and transferrin act by a similar receptor-mediated mechanism in which the transport protein recycles after endocytosis from the cell to undergo further rounds of intracellular transport.     

Low density lipoprotein binding induces asymmetric redistribution of the low density lipoprotein receptors in endothelial cells.

The uptake and transport of cholesterol-carrying low density lipoprotein (LDL) by the arterial wall is a continuous dynamic process, contributing to the cholesterol homeostasis in the plasma and in the cellular components of the vessel wall. Upon exposure to endothelial cells (EC), LDL interacts in part, with specific surface receptors (LDL-R). In this study we questioned: (i) the distribution of LDL receptors on the apical and basal cell membranes in endothelial cells; (ii) the role of LDL receptors in the control of cholesterol homeostasis and (iii) the translocation of LDL receptor across the EC. To this purpose bovine aortic EC were cultured on filters in a double-chamber system, in Dulbecco's medium supplemented either with 10% fetal calf serum (FCS) or with 10% lipoprotein-deficient serum (LPDS). The cells were exposed for 3h to 13H]acetate (40 microCi) added to both compartments of the cell culture inserts. The newly synthesized [3H]cholesterol was detected by thin layer chromatography and quantified by liquid scintillation counting. The LDL-R were detected in EC protein homogenates by immunoblotting using a monoclonal antibody against LDL-R (IgG-C7); the intracellular pathway of LDL-R was examined by electron microscopy using a complex made of protein A 5 nm or 20 nm colloidal gold particles and an anti-LDL receptor antibody (Au-PA-C7). To evaluate the distribution and the transport of LDL-R from one cell surface to the other, EC grown in LPDS were radioiodinated either on the apical or on the basolateral surface, incubated on the same surface with LDL, and subsequently biotinylated on the opposite non-radiolabeled surface. The EC were further solubilized and the protein extract immunoprecipitated with anti-LDL-R antibody or with mouse IgG (as control). The eluted antigen-antibody complexes were precipitated with streptavidin-agarose beads, solubilized, and subjected to SDS-PAGE. The results showed that: (a) the LDL-R were present on both endothelial cell fronts; (b) using the complex Au-PA-C7, the LDL-R were localized in endothelial plasmalemmal vesicles as well as coated pits and coated vesicles in multivesicular bodies and lysosomes, irrespective of the cell surface exposed to the complex; (c) biochemical assays indicated that upon ligand binding, the LDL-R were translocated preferentially from the apical to the basal plasma membrane.     

改良的高纯度人早孕绒毛膜滋养层细胞培养方法

目的培养纯度较高的人早孕绒毛膜滋养层细胞,为研究胎盘绒毛在妊娠期间的作用及其机制提供细胞学基础。方法胰蛋白酶-DNA酶消化法分离培养绒毛膜滋养层细胞,再运用流式细胞仪细胞分选获得高表达HLA-G的人早孕绒毛膜滋养层细胞。流式细胞术检测分选前后原代培养细胞HLA-G的表达率,相差显微镜观察滋养层细胞形态学特点,免疫荧光显微镜鉴定细胞来源,台盼蓝染色检测细胞活力。结果通过流式细胞检测,分选前的原代培养细胞体系中HLA-G的表达率为86.5%,经过分选带有PE荧光/HLA-G阳性表达的原代培养细胞后,其纯度可达98.0%。倒置相差显微镜下,可见细胞为上皮样细胞形态,呈片状铺展生长。细胞角蛋白染色阳性,波形蛋白染色阴性,表明细胞性质为上皮来源的绒毛膜滋养层细胞。台盼兰排斥试验检测细胞活力,细胞活力良好,存活率超过92%。结论该方法可以有效获得高纯度的,具有生物学活性的人早孕绒毛膜层细胞,为在体外研究生理妊娠及病理妊娠中滋养细胞的作用提供了一种改良的技术手段。     

Acetylated low-density lipoprotein is endocytosed through coated pits by rat peritoneal macrophages

The surface distribution of the scavenger receptors for acetylated low-density lipoprotein (acetyl-LDL) and their endocytic behavior were studied by the direct immunoperoxidase method using monomeric conjugates of horseradish peroxidase with Fab' antibody raised against LDL. The receptors were demonstrated to be distributed diffusely on the surface membrane of cultured peritoneal macrophages, with preferential localization in coated pit regions. With temperature shift from 4 degrees C to 37 degrees C, acetyl-LDL bound to the surface membrane rapidly disappeared, but became detectable in coated vesicles or lysosomes. Further incubation in the presence of acetyl-LDL revealed lipid vacuoles devoid of a limiting membrane in the cytoplasm, transforming macrophages into typical foam cells. These data suggest that the binding of acetyl-LDL to its receptors triggers the clustering of the receptors into the coated pit regions through which acetyl-LDL is endocytosed by coated vesicles to be degraded in lysosomes with subsequent intracellular accumulation of cholesterol esters.     

Coated and smooth vesicles participate in acetylcholine receptor transport

Summary The removal of the acetylcholine receptors (AChRs) from the surface of muscle cells serves as an important mechanism in the regulation of the AChR turnover rate. Our previous studies have shown that cultured myotubes contain coated pits and vesicles bearing -bungarotoxin (BTX)-binding sites (Bursztajn 1984; Bursztajn and Fischbach 1984). In this study we have used BTX conjugated to horseradish peroxidase (HRP) and quantitative electron microscopy to determine the intracellular pathway(s) of acetylcholine receptors during the internalization process. To accomplish this, cultured rat myotubes were incubated with BTX-HRP at 4° C after which cells were washed and incubated at 37° C for 0 min to 2 h. After warming the cells, coated pits, coated vesicles and smooth membraned vesicles containing the peroxidase reaction product were present. A threefold increase in coated vesicles containing the reaction product was observed 1 min after warming the cells. The number of smooth-membraned vesicles remained constant at this time point. However, 5 to 15 min after warming the cells, a fivefold increase in the number of smooth membraned vesicles was observed. After 1 h at 37° C the reaction product was present in the lysosomal like bodies, but was not observed in the Golgi complex or the small coated vesicles associated with the Golgi complex. Our observations indicate that there is a size segregation between those coated vesicles containing BTX-HRP reaction product and those in which reaction product is absent. Our studies also suggest that within minutes of AChR internalization coated vesicles lose their coat and become smooth-membraned vesicles.     

Variability of the topography of low-density lipoprotein (LDL) receptors in the plasma membrane of cultured human skin fibroblasts as revealed by gold-LDL conjugates in conjunction with the surface replication technique

In this investigation the membrane-perturbing effect of filipin, a polyene antibiotic which reacts specifically with cholesterol or cholesterol-like compounds in cell membranes, has been exploited to study the distribution of coated pits in cultured human skin fibroblasts. The coated pits, showing no filipin-cholesterol complexes, occurred singly or in clusters without apparent localization of either type to a particular region of the fibroblast membrane. Colloidal gold, conjugated to low-density lipoprotein, has proven to be an excellent marker, allowing the localization of low-density lipoprotein receptors on the surface of cultured cells. A pattern similar to that for the coated pits in the plasma membrane fracture faces was observed in the distribution of gold-low-density lipoprotein conjugates in surface replicas, indicating that the low-density lipoprotein receptors are associated with these coated pits. It was shown that there is an apparent heterogeneity in the distribution of low-density lipoprotein receptors, from cell to cell and even among different areas of the same cell membrane. The binding capacity for gold-low-density lipoprotein complexes, as represented by the extent of surface labeling, was directly related to the cell variety within the culture or to the particular experimental procedure. The observation of differences in the distribution of gold-low-density lipoprotein conjugates, even among adjacent coated pits, provides evidence for various stages of activity of the low-density lipoprotein receptors corresponding to incorporation, mobility, and internalization.     

Binding and uptake of Col 1(I), a peptide capable of inhibiting collagen synthesis in fibroblasts

Col 1(I), a collagenase-resistant segment of the amino-terminal propeptide of pro alpha 1(I) chains, is known to inhibit collagen synthesis in cultured skin fibroblasts and also in a cell-free protein synthesizing system by reducing the translation of procollagen mRNA. These findings prompted us to explore the fate of exogenous Col 1(I) in the cellular processing of human skin fibroblasts using colloidal gold labeled protein (Col 1(I)-Au). Distribution of Col 1(I)-Au on the cell surface was studied by the platinum-carbon replication technique. Three different types of binding pattern could be observed: 1) Binding sites in the form of a fibrillar network, 2) those in the form of clusters, and 3) solitary bound gold conjugates. The latter two cases were determined to be specific. The intracellular routing of Col 1(I)-Au was studied by thin sections. Specifically bound gold conjugates were found in coated pits and after the initiation of the internalization process in coated vesicles and endosomes. Acid phosphatase cytochemistry revealed that only a small amount of Col 1(I)-Au is delivered to lysosomes. The bulk of gold conjugates is present even after prolonged incubation at 37 degrees C in acid phosphatase-negative compartments of the cell. Our data suggest a mechanism in which Col 1(I) initially is bound to the cell surface and subsequently internalized via the coated pit-coated vesicle pathway.     

Binding and internalization of gold-conjugated somatostatin and growth hormone-releasing hormone in cultured rat somatotropes

Summary The synthetic peptides somatostatin (SRIF) and growth hormone-releasing hormone (GRH) were coupled directly to colloidal gold of different particle sizes. Both conjugates were biologically active in displacing the corresponding radiolabeled hormones from high affinity binding sites in pituitary membranes. Release of growth hormone (GH) from cultured anterior pituitary cells was modulated by both conjugates alone or in combination. Ultrastructural studies were performed with cells incubated at 4° C (2 h) and 37° C (2 min-2 h) with one of the labeled peptides or their combination. Somatotropes were identified by immunostaining with anti-rGH followed by protein A-ferritin, thus obtaining a triple labeling. Both hormone conjugates were internalized in different vesicles in the beginning but accumulated during longer incubation times in the same compartment. The secretory vesicles and the nucleus were not labeled by any hormone conjugate. In contrast to SRIF-gold, the uptake of GRH-gold conjugate decreased with longer incubation times. This effect could be neutralized by simulatenous incubation of the somatotropes with both regulating hormones. Hence, whereas the binding and internalization of SRIF by somatotropes do not seem to be influenced by GRH, the corresponding processes for GRH are stimulated by the presence of SRIF.     

Visualization of the interaction of native and modified low density lipoproteins with isolated rat liver cells

Morphological characteristics of the interaction of low density lipoproteins (LDL) and acetylated low density lipoproteins (AcLDL) with rat liver cells are described. These liver cell types are mainly responsible for the catabolism of these lipoproteins in vivo. Isolated rat liver Kupffer, endothelial, and parenchymal cells were incubated with LDL or AcLDL conjugated to 20 nm colloidal gold. LDL was mainly internalized by Kupffer cells, whereas AcLDL was predominantly found in endothelial cells. Kupffer and endothelial cells displayed different morphological characteristics in the processing of these lipoproteins. Kupffer cells bound LDL at uncoated regions of the plasma membrane often at the base of pseudopodia, and internalized the particles via small smooth vesicles. These uptake characteristics differ from the classical LDL uptake pathway, as described for other cell types, and may be related to the unique recognition properties of the receptor of Kupffer cells as observed in biochemical studies. Liver endothelial cells bound AcLDL in coated pits, followed by rapid uptake. Uptake proceeded through small coated vesicles, and after 5 min of incubation large (600-1200 nm) electron-lucent vacuoles (endosomes) with AcLDL-gold particles arranged along the membrane region were present. The endosomes were often associated closely with the cell membrane which might enable direct recycling of AcLDL receptors. These observations might explain the high efficiency of these cells in the processing of modified LDL in vivo.